3D Hydrogels Containing Interconnected Microchannels of

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Bio-interactions and Biocompatibility

3D Hydrogels Containing Interconnected Microchannels of Subcellular Size for Capturing Human Pathogenic Acanthamoeba Castellanii Sören B. Gutekunst, Katharina Siemsen, Steven Huth, Anneke Möhring, Britta Hesseler, Michael Timmermann, Ingo Paulowicz, Yogendra Kumar Mishra, Leonard Siebert, Rainer Adelung, and Christine Selhuber-Unkel ACS Biomater. Sci. Eng., Just Accepted Manuscript • DOI: 10.1021/acsbiomaterials.8b01009 • Publication Date (Web): 10 Jan 2019 Downloaded from http://pubs.acs.org on January 12, 2019

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ACS Biomaterials Science & Engineering

3D Hydrogels Containing Interconnected Microchannels of Subcellular Size for Capturing Human Pathogenic Acanthamoeba Castellanii Sören B. Gutekunst1, Katharina Siemsen1, Steven Huth1, Anneke Möhring1, Britta Hesseler1, Michael Timmermann1, Ingo Paulowicz3, Yogendra Kumar Mishra2, Leonard Siebert2,

Rainer Adelung2,

Christine Selhuber-Unkel*,1. 1

Institute for Materials Science, Biocompatible Nanomaterials,

University of Kiel, D-24143 Kiel, Germany 2

Institute for Materials Science, Functional Nanomaterials,

University of Kiel, D-24143 Kiel, Germany 3

Phi-Stone AG, D-24143 Kiel, Germany

CORRESPONDING AUTHOR: *E-mail: [email protected] KEYWORDS: 3D ceramic templates, microchannels, porous hydrogel, cell migration, human pathogens

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Abstract

Porous

hydrogel

cellular

scaffolds

are

microenvironments,

mechanical aspects.

We here

ideal both

candidates

regarding

present a

for

mimicking

structural

novel strategy

and

to use

uniquely designed ceramic networks as templates for generating hydrogels with a network of interconnected pores in the form of microchannels. The advantages of this new approach are the high and guaranteed interconnectivity of the microchannels, as well as the possibility to produce channels with diameters smaller than 7 µm. Neither of these assets can be ensured with other established techniques.

Experiments

using

the

polyacrylamide

substrates

produced with our approach have shown that the migration of human pathogenic Acanthamoeba castellanii trophozoites is manipulated by the microchannel structure in the hydrogels. The parasites can even be captured inside the microchannel network and were removed from

their

incubation

medium

by

the

porous

polyacrylamide,

indicating the huge potential of our new technique for medical, pharmaceutical and tissue engineering applications.

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1. Introduction The significant influence of the extracellular environment on a variety

of

cellular

proliferation,

processes

migration

and

such

as

cell

differentiation

adhesion,

has

recently

developed into a subject of high interest for cellular research.1-3 Cell migration, for instance, is controlled by the dimension4-5 as well

as

by

the

environment,6-7 constraints, limiting

mechanical

where

cell

nuclear

stiffness

factors8-10.

characterization

of

properties

of

the

deformability, and

cell

Therefore, microstructural

physical

adhesion the

extracellular

are

tissue

important

manipulation

properties

of

and

materials

provides novel opportunities to mimic extracellular environments in order to control cell migration. A biomedically highly relevant application for controlling cell migration is to capture pathogenic microorganisms. For example, micron-sized lobster traps have been fabricated from silicone to capture swimming bacteria.11 Such structure-based capture devices are very interesting, as they can provide cell capture without the requirement of additional chemical agents. The medical advantages of cell-capturing materials become quickly apparent considering pathogenic cells that rely on adhesion to their

surroundings.

extremely

motile14

A

medically

example

of

such

dangerous,12 pathogens

adhesive13 is

and

Acanthamoeba

castellanii (A. castellanii). Upon contact with the human eye,

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this amoeba invades the corneal tissue and leads to a painful and hard-to-treat blindness.15

Acanthamoeba This

is

an

keratitis,

which

especially

can

even

troubling

cause

issue

as

A. castellanii is found in a huge variety of environments such as water reservoirs (e.g. swimming pools or liquids for contact lens storage16) and soil, even despite disinfection procedures17. Thus, the infection chance during human everyday life is comparably high.18 A. castellanii infections are especially severe as the parasite’s motile trophozoite form can transform into doublewalled cysts under unfavorable conditions in order to protect itself

from

treatment

medication,

procedures

heat

extremely

or

even

radiation.

long-lasting

and

This

makes

complicated.19

Considering this, it is not only important to improve procedures that cure an A. castellanii infection, but also to find methods to avoid the infection in the first place. Conventional strategies to avoid

A. castellanii

infections

are

based

on

disinfection

procedures,20 which lack the efficiency to kill all the amoebae21 and strongly rely on the active cooperation of the potentially exposed person. Hence, they are prone to mistakes and capturing the

amoeba

using

microstructured

materials

poses

a

highly

promising alternative to these established methods. Here, we introduce a novel approach to capture A. castellanii by the structural features of a 3D porous material. To do so we produced bulk hydrogels containing a maze-like three-dimensional

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network

of

interconnected

microchannels

by

embedding

and

subsequently dissolving microfibrous zinc oxide (ZnO) scaffolds in Polyacrylamide (PAAm). The scaffolds are made of ZnO tetrapods, which are very unique three-dimensional structures with four arms interconnected via a central core at an angle of ~109° and with variable

sizes

in

the

micrometer

regime.22

By

pressing

such

tetrapods into a tablet and sintering them at high temperatures, a highly interconnected ZnO network can be produced that serves as sacrificial structure for microfibrous materials.23-24 When employed in combination with hydrogels, a unique microchannel network is formed

that

migration

can

and

be used

even

for

both

for

capturing

controlling A. these

parasites

castellanii from

their

incubation medium. Our findings indicate the high potential of this approach to lower the risk of A. castellani infections on a broad scale, as it can be used to produce materials to remove the parasites from water reservoirs or to inhibit amoebae migration, giving our approach a high medical, pharmaceutical and engineering relevance. 2. Materials and Methods Acanthamoeba Culture: Acanthamoeba castellanii trophozoites were cultured at room temperature in Peptone Yeast Glucose (PYG) 712 medium (20 g proteose peptone (BD, Sparks, USA), 1 g yeast extract (BD, Sparks, USA), 950 mL distilled water, 10 mL 0.4 (AppliChem, Darmstadt, Germany), 8 mL 0.05

M

M

MgSO4•7H2O

CaCl2 (AppliChem,

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Darmstadt,

Germany),

34 mL

0.1

M

sodium

Page 6 of 48

citrate·2H2O

(Merck,

Darmstadt, Germany), 10 mL 0.005

M

Fe(NH4)2(SO4)2•6H2O (AppliChem,

Darmstadt, Germany), 10 mL 0.25

M

Na2HPO4•7H2O (Roth, Karlsruhe,

Germany), 10 mL 0.25

M

KH2PO4 (Roth, Karlsruhe, Germany), 50 mL 2

M

glucose (Sigma–Aldrich Chemie GmbH, Steinheim, Germany)). The PYG medium was exchanged at least once a week to avoid cyst formation. Acanthamoebae were detached from the culture flask by slight knocking, collected with a pipette and centrifuged. The generated pellet was resuspended in PYG medium and the cell number was counted using a Neubauer counting chamber. Ceramic Porous Template Synthesis: Zinc oxide tetrapods (t-ZnO) were synthesized by using a single step flame transport synthesis approach.22-23 The tetrapods with arm diameter in the submicron regime and arm lengths ranging between 1 – 8 µm were utilized for fabrication of porous interconnected sacrificial templates for all cellular experiments. Thinner tetrapods for checking the influence of tetrapod diameter onto the resulting channel diameter (Fig. 4 D –F) were produced by adapting the flame transport synthesis: Whereas the conventional synthesis of the tetrapods presented above makes use of a sacrificial polymer (PVB) as a carbon source for zinc reduction, we now used ethanol in its stead. Furthermore, a turbulent air environment was created by applying a constant pressurized air flow of 90 l/min. Additional turbulent effects from

ethanol

combustion

as

well

as

a

short-term

temperature

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increase lead to a faster growth of thinner and longer tetrapod arms, partly connected by nanosails.25 In order to form the 3D sacrificial templates, tetrapods from one synthesis batch were filled and pressed into cylindrical alumina molds and the amount was chosen such that the density of the resulting network is 0.3 g/cm³, ~0.49 g/cm³, 0.6 g/cm³ or 1.0 g/cm³. The alumina templates with pressed ZnO tetrapods were annealed at high temperature (thick tetrapods at 1150 °C for 4.5 hours; thin tetrapods at 800 °C for 5 h) to form interconnections. For all cell experiments, we employed scaffolds with a density of 0.49 g/cm³. Template-Mediated

Polymerization

of

Microchannel-containing

Polyacrylamide: A mixture of acrylamide (Bio-Rad, 40 %, 1.00 mL), N,N’-methylenebisacrylamide

(Bis,

Bio-Rad,

2%,

200 µL),

HEPES

buffer (Sigma-Aldrich, pH = 7.5, 50.0 µL), and ammonium persulfate solution (Sigma-Aldrich, 10 %, aq., 75.0 µL) were filled up to a volume of 5.00 mL with bidest. water in a small beaker and degassed for 20 min in a desiccator.

The solution was poured on the t-ZnO

tablet with N,N,N’,N’-tetramethylethylenediamine (TEMED, Bio-Rad, 5.00 µL) and after 1 h of polymerization, the substrate was washed with and stored in bidest. water (AppliChem GmbH). Hydrolysis of the ZnO-Template Inside the Polyacrylamide: The ZnOtemplate was removed from the PAAm via hydrolyzation by three times incubating

the

hydrogel

in

hydrochloric

acid

(0.5

M,

Sigma-

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Aldrich) for a total of at least 24 hours. Afterwards, the hydrogel was washed with bidest. water (AppliChem GmbH) until it had a neutral pH value (pH adenosine

6 to 7) and was swollen to equilibrium in an

3’,5’-cyclic

monophosphate

solution

(cAMP,

Sigma-

Aldrich, 0.01 - 10.0 mM), which was exchanged daily, for 2 to 4 d. Samples were sterilized in 70 % ethanol for 15 min and washed under sterile conditions

for 24 h with

PYG

712 for A.

castellanii

experiments. Substrates were used within 48 h. Fluorescent Staining of the Microchannels: In order to render the microchannels of a PAAm sample fluorescent, the water was removed from the hydrogel by washing it repeatedly in ethanol (Walter CMP, Germany)

for

at

least

20

minutes,

increasing

the

ethanol

concentration with each washing step. The concentrations employed were 50%, 70%, 80%, 90%, 95% and 99%. Afterwards, the samples were incubated in an aqueous solution of Fluorescein isothiocyanate – Dextran

500000



Conjugate

(FITC-Dextran,

1.32

mg/ml,

Sigma-

Aldrich) overnight. Imaging of the Microchannels: Fluorescent z-stack images were recorded using a confocal microscope (Olympus, IX-81), equipped with a spinning disc unit (TILL Photonics, 1203-9-1-0017), a 488 nm Laser (Topica Photonics, iCHROME-MLE_LFA 3002) and an EM-CCD Digital Camera (Hamamatsu). The samples were placed upside down in glass-bottom petri dishes (ibidi, 81218-200). The surface at the bottom of the sample was focused, and the focus plane was shifted

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into the sample up to a point where background fluorescence became too strong (~70 µm – 220 µm into the sample). Z-stacks where recorded between these two focus planes with a step width of

1.99

µm. The z-stack top-views were computed using the xcellence rt software (Olympus, version 1.2). Cell Migration Experiments: The sterilized microchannel-containing PAAm samples were incubated with A. castellanii (ATTC 30234, 30.000 cells/mL) in PYG medium in a 6-well plate (Sarstedt). After 0.5 h - 2 h incubation time, phase contrast microscope images (Olympus, IX-81/BX-43) and movies (1 frame per 5 seconds) of the trophozoites inside the microchannels were recorded with a 10x objective using a monochrome (Hamamatsu, C-9300) or color camera (Imaging Source, DFK 31BF03). As control experiments, bulk PAAm samples were created as described above, but without applying a ZnO template, and swollen to equilibrium in cAMP. Image Analysis: Acanthamoeboa images were analyzed for the resting time, cell speed, and the direction of movement of the trophozoites inside the channels. Cell speed was determined by following the track of their front and rear inside a channel. The speed of the moving amoebae and their diameter perpendicular to the direction of motion was measured using ImageJ.26 The latter was interpreted as a measure for the channel diameter the cell was migrating through.

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Cell

Trapping

Efficiency

of

the

Page 10 of 48

Microchannel-Containing

Polyacrylamide Substrates: To quantify the efficiency with which our microstructured PAAm captures Acanthamoeba from incubation medium, we placed four PAAm substrates in one well of a 6-wellplate and incubated them with A. castellanii in PYG 712 medium (20000 cells per well). These experiments were performed in three technical repeats and also with blank wells as control. The number of cells in the supernatant of each well was counted with a Hemocytometer (Neubauer counting chamber, Hecht Glaswaren) after 2 h, 24 h, 48 h, and 120 h. Elasticity of Bulk Samples: Bulk samples without ZnO were prepared according to the prescription above. The polymer mixture was poured in PTFE molds with a diameter of 10 mm and 5 mm height. The samples were polymerized at room temperature for 1 h and then treated with either dest. water, 0.5 M hydrochloric acid or 1.28 M hydrochloric acid for 2 d. Afterwards, the samples were washed with dest. water until the pH of the solution was neutral (up to 6 d). The mechanical properties

of

the

swollen

samples

were

determined

with

an

indentation experiment using a modified tensile test setup. On one side, a stepper motor (M229.26S, Physik Instrumente GmbH & Co. KG, Germany) introduces a movement and on the other side, a load cell (KD24s 10N, ME-Meßsysteme GmbH, Germany) detects a force. To switch this setup to a tensile test setup a PTFE-sphere with a diameter of 6 mm was mounted to the moving arm of the stepper motor and a

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flat PTFE plate was mounted to the load cell. PTFE was chosen for reducing the friction between the surfaces and the sample. For the measurement the sphere was moved to a predefined position above the sample. Afterwards, it was lowered by 3 mm with a velocity of 0.1 mm/s,

resulting

in

an

indentation

of

the

sample.

The

indentation depth varied between the samples, because start- and endpoint

of

the

measurement

were

predefined

and

the

sample

thickness varied.

Figure 1. (A) Exemplary SEM image of a ZnO tetrapod, which serves as basic constituent of sacrificial templates for the production of microchannel-containing hydrogels. The SEM images allow the determination of the tetrapod size by image analysis.

A histogram

of the tetrapod diameter, measured at the base of the tetrapod arms is shown in (B). The distribution ranges from 1.5 µm to 8.75 µm and peaks at 3 µm.

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3. Results We synthesized ZnO tetrapods, pressed them into a tablet and sintered this tablet to ensure interconnectivity of the tetrapods in the resulting ZnO network. Fig. 1A shows an exemplary Scanning Electron Microscopy (SEM) image of a ZnO tetrapod, the size of which can be easily determined by image analysis. Fig. 1B shows a histogram of the diameters of 105 tetrapod arms, measured at their base. These diameters range from 1.5 µm to 8.75 µm and their distribution peaks at 3 µm. The ZnO tetrapod tablet was immersed in a solution of Acrylamide and BIS Acrylamide, which was then polymerized to form PAAm. A phase contrast image of the tetrapod tablet, embedded in the polyacrylamide gel, is shown in Fig. 2A. When such a ZnO-containing PAAm sample was incubated in hydrochloric acid, the ZnO template dissolved, leaving microchannels in the hydrogel. In Fig. 2B, the dissolving process is shown macroscopically and its final stages are

captured

microscopically

(Fig.

2C)

at the

center

of the

original tablet, showing that no ZnO tetrapods were left after the hydrolysis. The sample was then washed excessively in aqua bidest. to remove all the dissolved ZnO and other reaction products, thus resulting in microchannels inside the PAAm (Fig. 2D). As the tetrapods had been pressed to high densities and were sintered at high temperatures prior to embedding them in the hydrogel, the ZnO

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network

in

the

PAAm

was

fully

interconnected

and

hence

the

microchannels, which remained in the hydrogel as a negative imprint of

this

ZnO

network

after

its

dissolution,

were

also

interconnected. In other words, the hydrogel now contained a network of cylindrically shaped, interconnected microchannels with larger cavities at the junctions of several of these channels. Fig. 3 visualizes the different fabrication steps of our procedure.

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Figure 2. The ZnO tetrapods are pressed

and

sintered

interconnected embedded

ZnO

into

into

network

an

an and

Acrylamide

solution, which is then allowed to polymerize. A phase contrast image of the ZnO network in the PAAm hydrogel is presented in (A). The ZnO PAAm

network

dissolves

sample

is

when

the

incubated

in

hydrochloric acid (HCl). (B) and (C)

both

present

starting

from

time

the

arrays

left

that

recorded the dissolution process. (B)

shows

the

whole

process

macroscopically while (C) displays phase contrast images of the last stages of the hydrolysis, recorded microscopically every 15 minutes

at

the

center

of

the

tablet,

showing

that

the

non-

transparent ZnO structures dissolve completely. The ZnO structures leave an interconnected network of microchannels in the PAAm gel, as shown in a phase contrast image in D.

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For better visualization of the channels, we filled them with a FITC-Dextran conjugate (which entered the microchannels, but not the hydrogel itself), and imaged z-stacks of the samples with a confocal microscope. Exemplary top-views of z-stack composites are presented in Fig. 4. For each of two different tetrapod diameter ranges (A – C and D – F, respectively), three different samples with different tetrapod densities (0.3 g/cm³ in A and D, 0.6 g/cm³ in B and E, 1 g/cm³ in C and F) were produced and for each sample, one image is given. The images show that the densities as well as diameter ranges of the resulting microchannels can be controlled by

manipulating

scaffold.

the

respective

property

of

the

sacrificial

The density can be varied by adapting the amount of ZnO

tetrapods added to the sample as well as by changing the pressure applied during the sintering process. More tetrapods as well as higher pressures increase the network density. The diameter ranges of the tetrapods and hence the microchannels can be varied by parameters of the tetrapod production process.27 To investigate the impact of our 3D hydrogel microstructure on the migration

of

Acanthamoebae,

we

incubated

our

microchannel-

containing PAAm with A. castellanii trophozoites, which readily adhered to the PAAm without further surface functionalization. As A. castellanii

is

responsive

monophosphate solution (cAMP),

28

to

adenosine

3’,5’-cyclic

the hydrogels were soaked in cAMP

prior to cell experiments to accelerate migration into the hydrogel

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scaffold. Two very interesting and striking effects became quickly apparent: Firstly, in spite of their typical diameter of 12 µm – 35 µm,12 A. castellanii trophozoites were able to migrate through microchannels with diameters down to a few microns to explore the material (Fig. 5A). Secondly, the trophozoites often remained immotile for several hours when reaching larger cavities at the junctions of the microchannels inside the PAAm (Fig. 5B).

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Figure

3.

Synthesis

of

microchannel-containing

polyacrylamide

hydrogels. First, a sintered zinc oxide tetrapod based network template (black) with a well-defined tetrapod density is embedded into

an

Acrylamide

polyacrylamide

solution,

(PAAm,

which

green).

is

then

Afterwards,

polymerized

the

template

to is

hydrolyzed with hydrochloric acid (HCL), leaving a negative of microchannels inside the PAAm (white). After complete hydrolysis of

the

ceramic

template,

the

PAAm

is

washed

and

swollen

to

equilibrium in cAMP solution. Now, the material can be used for cell experiments (orange). As the tetrapod template was sintered and

produced

at

high

tetrapod

densities,

the

network

of

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microchannels in the PAAm, being a negative of this template, is highly interconnected.

Figure 4. Top-view of a z-stack of confocal fluorescence microscopy images of the microchannels in PAAm hydrogels. The images present channels resulting from tetrapod scaffolds with different network densities and diameters. Images A – C correspond to the samples produced by using tetrapods with larger diameters, while samples

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shown in D – F were produced using thinner tetrapods. Each column of images pictures samples from one ZnO density in the tetrapod template. Namely 0.3 g/cm³ (A and D), 0.6 g/cm³ (B and E) and 1 g/cm³ (C and F). It becomes clear that the ranges of channel diameters

and

densities

parameters of the

are

influenced

sacrificial ZnO

by

these

template and

can

respective hence

be

controlled by adapting the template properties.

Figure 5. (A) Phase contrast images of A. castellanii moving through the microchannels inside the PAAm. The circle indicates an Acanthamoeba migrating into a side channel (Ø = 6.5 µm). (B) Several Acanthamoebae are stuck in a microchannel junction (arrow) and an Acanthamoeba is stuck inside a cavity. The Acanthamoeba probes the surrounding channels with its Acanthapodia (rectangle).

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To quantify these effects further, movies were taken over several hours (here: 16 h; Supplementary Movie 1) and analyzed for cell migration

speed,

cell

diameter

(measured

perpendicular

to

direction of movement, hence corresponding to the size of the microchannel that the amoeba was squeezing through) as well as the percentage of migrating and resting A. castellanii trophozoites. As a control, we carried out the same analysis on A. castellanii migrating on bulk PAAm samples. The results are presented in Fig. 6 and demonstrate that A. castellanii trophozoites squeezed into channels of diameters down to 6.5 µm. No migrating cells were observed in channels smaller than this. Furthermore, no apparent correlation of cell migration speed with the channel diameter was observed, but A. castellanii migrating on bulk PAAm samples were able to reach velocities almost twice as high as the ones in the microchannel networks (Fig. 5A). that

more

than

50%

of

the

Even more strikingly, we found A. castellanii

trophozoites

in

microchannel-containing PAAm were resting in cavities while amoeba migrating on bulk PAAm samples were always in motion (Fig. 5B), underlining

the

significance

of

the

influence

that

our

new

microchannel network in the PAAm gels has on cell migration. An Acanthamoeba was defined as “resting” if it stayed inside a cavity for at least 40 sec. This value was chosen heuristically due to the length of our movies. In some experiments, the trophozoites

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stayed inside a cavity even for several hours. It is noteworthy that A. castellanii trophozoites are very motile and clearly do not rest on flat, unstructured substrates. Experiments carried out at longer timescales demonstrated that A. castellanii trophozoites stayed in the microchannel network inside our PAAm substrate for at least 6 days. They continued to migrate and to exhibit intracellular motion, while no encystment, but very high trophozoite densities were observed in the channels (Fig. 7). These rising cell densities motivated the idea that the specific 3D architecture of microchannels in combination with larger cavities in our hydrogels might provide the opportunity to capture A. castellanii from liquids with our new material. Hence, we incubated microchannel-containing PAAm samples up to 120 h with A. castellanii in PYG medium and repeatedly counted the number of cells in the supernatant of the medium (Fig. 8). As a control, we repeated these experiments in cell culture dishes without PAAm. After 24 h and 48 h incubation time, the amount of Acanthamoeba was slightly higher in the medium of the microchannel-containing PAAm, but after 120 h the presence of the microporous material had led to a significantly lower amount of A. castellanii in the supernatant compared to the medium of the bulk control (Fig. 8).

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Figure 6. A. castellanii migration inside the microchannels of PAAm. (A) shows the migration speed plotted versus the diameter of the channel the trophozoite was squeezing through. The violet circles

on

the

right

represent

the

migration

speeds

of

A.

castellanii cells on bulk PAAm samples. It becomes clear that A. castellanii trophozoites can squeeze into channels with diameters as small as 6.5 µm. No cells were observed below that (hatched area). Besides, there is no correlation of cell migration speed with channel diameter, but trophozoites on bulk samples can reach maximum migration speeds almost twice as high as the ones in the microchannels.

(B)

Percentages

of

resting

and

moving

A.

castellanii trophozoites on bulk samples (total number N = 18) and in the microchannel network in our PAAm sample (N = 83). While all amoebae were in motion on bulk samples, 54.2% of the cells in the microchannel-containing materials were resting in cavities at the junctions of several microchannels.

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4. Discussion We have introduced a new technique to produce microstructured 3D hydrogels

as

cell

substrates

by

pressing

and

sintering

ZnO

tetrapods into an interconnected network, which is immersed in an Acrylamide solution prior to polymerization. When the solution has polymerized, the tetrapod network is removed from the resulting PAAm hydrogel by hydrolysis with HCl. We have shown that this approach

produces

interconnected microns

and

PAAm

substrates

microchannels

that

these

with

porous

containing

diameters

materials

a

down

can

be

network to

only

used

as

of few 3D

substrates to study and manipulate the migration behavior of A. castellanii trophozoites.

Figure 7. Phase contrast image of densely packed A. castellanii inside the polyacrylamide microchannel network after one day of

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Page 24 of 48

incubation, revealing that the amoebae agglomerate as trophozoites in our substrate on longer time scales.

This, however, is just one among the many possible applications of these tetrapod-based materials in engineering and corresponding applications.

In

fact,

following

the

strategy

of

material

deposition and subsequent removal of an underlying template, 3D hollow tetrapodal networks with tunable dimensions (from nanometer to micron-scale) and ultrahigh porosities (up to 98%) can in principle

be

easily

realized

also

using

many

other

ceramic

materials. For instance, the 3D ceramic templates have already been successfully produced from several oxides, nitrides, silcon, etc. Since zinc oxide is easily hydrolyzed by acids,12 it was chosen for the present experiments as the sacrificial template material. Furthermore, all polymers that withstand acidic environments can be microstructured. In other words, using our new approach, a huge variety

of

materials

can

be

equipped

with

a

network

of

interconnected microchannels with many different channel diameters and densities (i.e. pore sizes, pore distribution and porosity).

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Figure

8.

The

number

of

A.

castellanii

in

the

medium

after

incubation with a microchannel-containing PAAm sample (black) or an empty cell culture dish (red) shows that although initially more trophozoites remain in the medium when incubated with the microstructured PAAm substrate, this changes strongly after 120 h incubation time, indicating the potential of our new substrate to remove amoebae from liquids.

We rendered the channels in the hydrogels fluorescent (Fig. 4), enabling us to measure channel diameters and densities directly in the hydrogel samples. Furthermore, by analyzing confocal z-stack slices

(Fig.

4),

it

is

possible

to

determine

the

number

of

junctions as well as their positions (Figure S3). This allows describing microchannel sizes and distributions in the sample (Figure S4). The porosity of the sample can also be determined

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using these z-stack slices. The porosity Φ is defined as the ratio of the volume of void space (i.e. of our channels) to the total sample volume. The total channel volume directly after the ZnO dissolution process is equal to the total volume of the tetrapod network and can hence be calculated from the weight of the sacrificial ZnO template, as the density of ZnO is known. The porosity can then be expressed as29: 𝛷 =

𝑉𝑍𝑛𝑂 𝑉𝑃𝐴𝐴𝑚 + 𝑉𝑍𝑛𝑂

=1―

𝑉𝑃𝐴𝐴𝑚 𝑉𝑃𝐴𝐴𝑚 + 𝑉𝑍𝑛𝑂

(1)

with VPAAm and VZnO as the volume of PAAm or ZnO, respectively. Hence, the initial PAAm porosity can be increased by increasing the amount of ZnO tetrapods in the sacrificial template. However, as the hydrogel continues to swell after ZnO dissolution,30 and since the description in eq. 1 does not take local variations of channel densities or diameters into account, it is recommendable to evaluate the microporosity at the region of interest using fluorescence images (Fig. 4). Using image analysis, the fraction of fluorescent pixels to the total amount of pixels of each slice of

the

z-stack

can

be

calculated

and

hence

gives

the

local

microporosity of the swollen gel. In general, we suggest to be careful with global descriptions of the samples produced with our approach since – as seen in Fig. 1B – the tetrapods constructing the sacrificial network do not have one distinct diameter, but a distribution of diameters. The same

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holds for the density of the tetrapod network and indeed, different positions of the

microchannel-containing PAAm samples display

different channel densities. Nevertheless, the properties of the channel network can be tuned as displayed in Fig. 4, but it is rather useful to consider this as an adaption of ranges of channel densities and diameters. Another important aspect is to realize that the shape of tetrapod arms (Fig. 1A) results in channels that vary their diameter across channel length. In general, the fluorescent imaging of the channels is very useful to gain a quick overview of the networks’ properties in order to optimize

production

parameters

for

specific

experimental

requirements. The fluorescent dextrane was chosen such that it entered the microchannels, but not the intrinsic pores of the hydrogel. This strategy can also be used to characterize the sample on

many

different

positions

and

hence

to

apply

statistical

descriptions of global network properties or they can be directly taken at a specific region of interest to gain exact knowledge about sample characteristics at this region. However, it is very useful and accurate to determine the channel diameter of interests in situ during cell experiments by evaluating the cell diameter perpendicular to cellular motion while it is migrating through this channel. As the cells need to be optically observed anyway, this does not impose a lot of extra work, but results in the most reliable and quick determination of the relevant channel diameters

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Page 28 of 48

during cellular experiments. This approach overcomes potential issues originating from not having channels with one distinct diameter

in

the

sample,

but

rather

turns

this

fact

into

an

advantage, as the influence of a variety of diameters on cell migration

is

Furthermore, situations

automatically this

more

variety

analyzed of

accurately,

with

diameters as

one

experiment.

resembles

physiological

in

vivo

extracellular

environments are not homogeneous at the cell scale.31 Similar assumptions hold for channel densities and the appropriate channel density can be chosen by simply changing the position at which experiments are carried out. PAAm

was

chosen

for

the

hereby

presented

experiments

since

hydrogels are very attractive for many biological applications,32 as they are soft33 and can support nutrient supply due to their intrinsic nanoporosity34. Specifically, PAAm is often used in cell adhesion experiments because its elastic properties can be defined by cross-linker density in a wide and physiologically important range and its surface can easily be functionalized.22-23 The Young’s modulus of the polyacrylamide produced in these experiments was approximately 19 kPa (Supplementary Information, Table S1), thus being in the range of the matrix elasticity that ensures A. castellanii adhesion.35 In general, the fabrication of mechanically robust 3D materials with well-defined porosities, pore shape and pore organization to

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control cell migration is highly desirable. However, achieving sufficient

mechanical

strength,

and

simultaneously

adjustable

porosities as well as interconnectivity in soft 3D architectured materials is a very challenging task. Fabrication of such materials requires complicated processing steps involving high costs.36-38 In addition,

micron-sized

pores

are

often

introduced

into

bulk

materials by applying conventional salt-leaching or gas foaming methods.39-40 The pores generated by these conventional methods typically have diameters of several tens of micrometers, and are inverse-opal shaped so that many cells can enrich within a single pore.41 Hence, cells in such large pores rather adhere on curved 2D surfaces without being completely surrounded by the material, as it is the case in our microchannels. Furthermore, the materials fabricated

by

salt-based

pore-leaching

require

large

pore

fractions in order to guarantee pore interconnectivity, which imposes a large structural limitation. Gas foaming techniques lack the control of pore interconnectivity and often pose problems in form of processing residuals in the material.42 Such limitations are

overcome

by

our

novel

approach,

since

we

can

produce

microchannels with high interconnectivity and diameters of down to only a few microns due to the special microstructure of the sacrificial ceramic template. Furthermore, our approach can easily be

upscaled

to

fabricate

large

amounts

of

microstructured

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materials, which is challenging for many other techniques such as 3D printing or cryogelation.42 It is also very interesting that most of recent advancements in microporous

hydrogel

concentrate

on

anisotropy

of

the

pore

structures or increasing the mechanical strength of structured hydrogels.42

Our

approach

concentrates

on

the

creation

of

hydrogels, which cells can enter freely and in which they can migrate and proliferate without exiting the sample, so that we can study them on long time scales. Incubating A. castellanii cells on our new microchannel-containing PAAm revealed not only that the cells willingly enter and migrate inside the microchannels (Fig. 4A), even with diameters much smaller than the cell diameter, but also that the maximum migration speed inside the channels is slower than on conventional 2D substrates (Fig. 5A) and - most strikingly - that A. castellanii even cease migrating when reaching cavities that had formed at microchannel intersections within the network (Fig.

4B).

The

Acanthamoebae

latter

are

is

always

in

particularly motion

on

interesting, the

surface

because of

bulk

polyacrylamide samples, whereas more than 50% of the amoeba in microchannel-containing

materials

were

resting

during

our

experiments (Fig. 5B). This result is in agreement with a previous study

that

has

reported

a

decrease

in

cell

migration

with

increasing pore size.27 Interestingly, cancer cells on the other hand have been found to increase their migration speed in narrow

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channels,43

indicating

the

change

of

cell

migration

speed

in

refined spaces to be a complex phenomenon, which is worth studying. It is noteworthy that in our experiments cells accumulate in much smaller pores compared to the large pores between 96 and 151 µm in size used by Harley et al.27, demonstrating that the effect of cell accumulation is also present for small pores. In other words, the parasites were captured by the microchannel network structure of our material, which is highly interesting as this indicates that implementing these structures into,

for example, conventional

contact lens materials, whose high water contents particularly favor A. castellanii growth and hence pose a high infection risk on contact lens users

13, 14,

would significantly decrease this

infection risk by keeping the parasites inside the material, where they cannot reach the corneal tissue. It is also important to note here that the trophozoites did not encyst, hence they might be removed without the formation of cysts, which would make them resistant against standard disinfection treatments.44 Despite having a cell diameter of 12 µm – 35 µm,12 A. castellanii trophozoites

were

able

to

migrate

through

microchannels

with

diameters down to 6.5 µm (Fig. 5A). The existence of this lower limit

to

diameters

that

A.

castellanii

can

squeeze

into

is

reminiscent of that of cells in collagen networks, where cell motion is stopped, if collagen fibers are too dense.9 Previous studies

on

mammalian

cells

have

shown

that

the

nuclear

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Page 32 of 48

deformability is a critical parameter in 3D cell migration.8 The nucleus of A. castellanii trophozoites is one sixth of the cell diameter with approximately 4.5-6.7 µm in size,45 hence this can explain the abrupt absence of migrating cells in channels below 6.5 µm in diameter. Another study has shown that cancer cell migration is impeded in channels with diameters below 7 µm, which is in agreement with our results.43 Another

very

striking

observation

we

made

was

that

the

trophozoites entering and remaining in the hydrogel leads to a decreased amount of A. castellanii in the incubation medium, which means that our new microchannel PAAm can be applied to remove these amoebae

from

water

reservoirs.

Since

the

presence

of

A. castellanii in such reservoirs also enhances the invasiveness of

Legionella

relevance.

pneumophila,16

this

is

high

of

general

medical

In contrast to other approaches to remove pathogenic

microorganisms from solutions, which are mainly based on chemical capturing46 and magnetic capturing47, our approach is solely based on the structural features of the porous hydrogel. This is a clear advantage because the structure is stable, the material is nondegradable and it can be cheaply and efficiently fabricated in high-throughput

mode.

Conclusion

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In conclusion, our strategy of using porous ceramic templates to incorporate

interconnected,

labyrinth-like

structures

of

microchannels into hydrogels provides novel, easy-to-fabricate 3D scaffolds

for

controlling

and

studying

cell

migration.

As

demonstrated, the specific organization and size distribution of microchannels A. castellanii

in by

the

material

structural

even

material

allows cues,

to

capture

providing

an

innovative high-throughput strategy for preventing Acanthamoebaborn diseases by, e.g., avoiding Acanthamoeba contaminations in contact lens storage cases or water reservoirs. In addition to capturing pathogenic microorganisms, future applications in tissue engineering are highly promising, as in that case the large surface fraction of the cell-material contact in the microchannels can be exploited for controlling cell functions that are induced by this cell-material contact.

ASSOCIATED CONTENT Supporting Information. Description and results of experiments to characterize the elastic properties as well as the swelling behavior of microchannel-containing PAAm samples. (PDF) Supplementary Movie S1: Time array of phase contrast images with a total duration of 16 h of A. castellanii trophozoites

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Page 34 of 48

migrating inside the microchannels of a microstructured PAAm substrate produced with the presented technique. (avi) Acknowledgements We acknowledge funding from the Deutsche Forschungsgemeinschaft (DFG) through the GRK 2154 and the SFB 1261, as well as from the ARVO Foundation (Vistakon Contact Lens Research Fellowship), and the European Research Council (Proof of Concept Grant 768740, Starting Grant 336104). R. A. thanks the DFG for financial support under

the

scheme

AD

183/17-1.

We

thank

Matthias

Leippe

for

providing A. castellannii, Supattra Paveenkittiporn for support with cell migration experiments and data acquisition, Katharina Göpfert for preparing porous substrates, Yannic Hallier for ZnO tetrapod characterization, and Manuela Lieb for support in the lab.

ABBREVIATIONS PAAm: Polyacrylamide t-ZnO: Zinc oxide tetrapods PYG: Peptone Yeast Glucose

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References 1.

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3D Environments Is Determined by a Combination of Adhesiveness, Nuclear Volume, Contractility, and Cell Stiffness. Biophysical Journal 109 (5), 900-913. DOI: 10.1016/j.bpj.2015.07.025. Di Giacomo, R.; Krödel, S.; Maresca, B.; Benzoni, P.; Rusconi, R.; Stocker, R.; Daraio, C., Deployable micro-traps to sequester motile bacteria. Scientific Reports 2017, 7, 45897. DOI: 10.1038/srep45897. Khan, N. A., Acanthamoeba : biology and increasing importance in human health. FEMS Microbiology Reviews 2006, 30 (4), 564595. DOI: 10.1111/j.1574-6976.2006.00023.x. Huth, S.; Reverey, J. F.; Leippe, M.; Selhuber-Unkel, C., Adhesion forces and mechanics in mannose-mediated acanthamoeba interactions. PLOS ONE 2017, 12 (5), e0176207. DOI: 10.1371/journal.pone.0176207. Preston, T. M.; King, C. A., Amoeboid locomotion of Acanthamoeba castellanii with special reference to cellsubstratum interactions. Journal of general microbiology 1984, 130 (9), 2317-23. Moore, M. B., Acanthamoeba Keratitis. Arch Ophthalmol-Chic 1988, 106 (9), 1181-1183. Seal, D.; Stapleton, F.; Dart, J., Possible environmental sources of Acanthamoeba spp in contact lens wearers. Br. J. Ophthalmol. 1992, 76 (7), 424-427. DOI: 10.1136/bjo.76.7.424. Marciano-Cabral, F.; Cabral, G., Acanthamoeba spp. as Agents of Disease in Humans. Clinical Microbiology Reviews 2003, 16 (2), 273-307. DOI: 10.1128/CMR.16.2.273-307.2003. Thomas, V.; McDonnell, G.; Denyer, S. P.; Maillard, J.-Y., Free-living amoebae and their intracellular pathogenic microorganisms: risks for water quality. FEMS Microbiology Reviews 2010, 34 (3), 231-259. DOI: 10.1111/j.15746976.2009.00190.x. Lorenzo-Morales, J.; Khan, N. A.; Walochnik, J., An update on Acanthamoeba keratitis: diagnosis, pathogenesis and treatment. Parasite 2015, 22, 10. DOI: 10.1051/parasite/2015010. Reverey, J. F.; Fromme, R.; Leippe, M.; Selhuber-Unkel, C., In vitro adhesion of Acanthamoeba castellanii to soft contact lenses depends on water content and disinfection procedure. Cont Lens Anterior Eye 2014, 37 (4), 262-266. DOI: 10.1016/j.clae.2013.11.010. Coulon, C.; Collignon, A.; McDonnell, G.; Thomas, V., Resistance of Acanthamoeba Cysts to Disinfection Treatments Used in Health Care Settings. Journal of Clinical Microbiology 2010, 48 (8), 2689-2697. DOI: 10.1128/JCM.0030910.

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For Table of Contents Use Only.

3D Hydrogels Containing Interconnected Microchannels of Subcellular

Size

for

Capturing

Human

Pathogenic

Acanthamoeba Castellanii Sören

B.

Gutekunst,

Möhring, Britta

Katharina

Hesseler,

Siemsen,

Steven

Huth,

Anneke

Michael Timmermann, Ingo Paulowicz,

Yogendra Kumar Mishra, Leonard Siebert,

Rainer Adelung, Christine

Selhuber-Unkel

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Figure 1 160x69mm (300 x 300 DPI)

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Figure 2 95x170mm (300 x 300 DPI)

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Figure 3 69x120mm (300 x 300 DPI)

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Figure 4

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Figure 5

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Figure 6 160x62mm (300 x 300 DPI)

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Figure 7 125x70mm (300 x 300 DPI)

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Figure 8 287x201mm (300 x 300 DPI)

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